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1. Phages on filaments: A genetic screen elucidates the complex interactions between Salmonella enterica flagellin and bacteriophage Chi

   https://doi.org/10.1371/journal.ppat.1011537  

   Esteves, Nathaniel C; Bigham, Danielle N; Scharf, Birgit E (August 2023, PLOS Pathogens)

   Navarre, William (Ed.)

   The bacterial flagellum is a rotary motor organelle and important virulence factor that propels motile pathogenic bacteria, such asSalmonella enterica, through their surroundings. Bacteriophages, or phages, are viruses that solely infect bacteria. As such, phages have myriad applications in the healthcare field, including phage therapy against antibiotic-resistant bacterial pathogens. Bacteriophage χ (Chi) is a flagellum-dependent (flagellotropic) bacteriophage, which begins its infection cycle by attaching its long tail fiber to theS.entericaflagellar filament as its primary receptor. The interactions between phage and flagellum are poorly understood, as are the reasons that χ only kills certainSalmonellaserotypes while others entirely evade phage infection. In this study, we used molecular cloning, targeted mutagenesis, heterologous flagellin expression, and phage-host interaction assays to determine which domains within the flagellar filament protein flagellin mediate this complex interaction. We identified the antigenic N- and C-terminal D2 domains as essential for phage χ binding, with the hypervariable central D3 domain playing a less crucial role. Here, we report that the primary structure of theSalmonellaflagellin D2 domains is the major determinant of χ adhesion. The phage susceptibility of a strain is directly tied to these domains. We additionally uncovered important information about flagellar function. The central and most variable domain, D3, is not required for motility inS. Typhimurium 14028s, as it can be deleted or its sequence composition can be significantly altered with minimal impacts on motility. Further knowledge about the complex interactions between flagellotropic phage χ and its primary bacterial receptor may allow genetic engineering of its host range for use as targeted antimicrobial therapy against motile pathogens of the χ-host generaSalmonella,Escherichia, orSerratia. 

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2. A Phage‐Based Approach to Identify Antivirulence Inhibitors of Bacterial Type IV Pili

   https://doi.org/10.1111/1751-7915.70081  

   Shimozono, Tori_M; Vogelaar, Nancy_J; O'Hara, Megan_T; Yang, Zhaomin (January 2025, Microbial Biotechnology)

   ABSTRACT The increasing threat of antibiotic resistance underscores the urgent need for innovative strategies to combat infectious diseases, including the development of antivirulants. Microbial pathogens rely on their virulence factors to initiate and sustain infections. Antivirulants are small molecules designed to target virulence factors, thereby attenuating the virulence of infectious microbes. The bacterial type IV pilus (T4P), an extracellular protein filament that depends on the T4P machinery (T4PM) for its biogenesis, dynamics and function, is a key virulence factor in many significant bacterial pathogens. While the T4PM presents a promising antivirulence target, the systematic identification of inhibitors for its multiple protein constituents remains a considerable challenge. Here we report a novel high‐throughput screening (HTS) approach for discovering T4P inhibitors. It usesPseudomonas aeruginosa,a high‐priority pathogen, in combination with its T4P‐targeting phage, φKMV. Screening of a library of 2168 compounds using an optimised protocol led to the identification of tuspetinib, based on its deterrence of the lysis ofP. aeruginosaby φKMV. Our findings show that tuspetinib also inhibits two additional T4P‐targeting phages, while having no effect on a phage that recognises lipopolysaccharides as its receptor. Additionally, tuspetinib impedes T4P‐mediated motility inP. aeruginosaandAcinetobacterspecies without impacting growth or flagellar motility. This bacterium‐phage pairing approach is applicable to a broad range of virulence factors that are required for phage infection, paving ways for the development of advanced chemotherapeutics against antibiotic‐resistant infections. 

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3. Chemical inhibition of a CBASS anti-bacteriophage defense

   https://doi.org/10.1101/2025.09.19.677395  

   Zhang, Chengqian; Rechkoblit, Olga; Gerdt, Joseph P (September 2025, bioRxiv)

   ABSTRACT Multidrug-resistant (MDR) bacteria pose a significant public health challenge, underscoring the urgent need for innovative antibacterial strategies. Bacteriophages (phages), viruses that specifically target bacteria, offer a promising alternative; however, bacterial immune defenses often limit their effectiveness. Developing small-molecule inhibitors of these defenses can facilitate mechanistic studies and serve as adjuvants to enhance phage therapy. Here, we identify novel inhibitors targeting the bacterial cyclic oligonucleotide-based anti-phage signaling system (CBASS) effector Cap5. Cap5 is an HNH endonuclease activated by a cyclic nucleotide to degrade genomic DNA in virally infected cells, leading to cell death through abortive infection. Guided by the crystal structure of the Cap5 SAVED domain bound to its activating ligand, we performed structure-guided virtual screening to identify candidate inhibitors. Biochemical assays revealed that approximately 16% of the top docking hits exhibited inhibitory activity. Further cellular assays demonstrated that one potent compound could enterE. colicells and inhibit Cap5 activity. Our integrated approach—combining structure-based virtual screening with biochemical validation—provides a robust framework for discovering small-molecule inhibitors of bacterial immune defenses to advance adjunctive therapies and deepen our understanding of phage-bacteria interactions. 

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4. Leveraging mathematical modeling framework to guide regimen strategy for phage therapy

   https://doi.org/10.1371/journal.pcsy.0000015  

   Yu, Zhiyuan; Luong, Tiffany; Banuelos, Selenne; Sue, Andrew; Ryu, Hwayeon; Segal, Rebecca; Roach, Dwayne R; Huang, Qimin (November 2024, PLOS Complex Systems)

   Kim, Jaehee (Ed.)

   Bacteriophage (phage) cocktail therapy has been relied upon more and more to treat antibiotic-resistant infections. Understanding of the complex kinetics between phages, target bacteria, and the emergence of phage resistance remain hurdles to successful clinical outcomes. Building upon previous mathematical concepts, we develop biologically-motivated nonlinear ordinary differential equation models to explore single, cocktail, and sequential phage treatment modalities. While the optimal pairwise phage treatment strategy was the double simultaneous administration of two highly potent and asymmetrically binding phage strains, it appears unable to prevent the evolution of resistance. This treatment regimen did have a greater lysis efficiency, promoted higher phage population sizes, reduced bacterial density the most, and suppressed the evolution of resistance the longest compared to all other treatments strategies tested. Conversely, the combination of phages with polar potencies allows the more efficiently replicating phages to monopolize susceptible host cells, thereby quickly negating the intended compounding effect of cocktails. Together, we demonstrate that a biologically-motivated modeling-based framework can be leveraged to quantify the effects of each phage’s properties to more precisely predict treatment responses. 

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5. Mutant and Recombinant Phages Selected from In Vitro Coevolution Conditions Overcome Phage-Resistant Listeria monocytogenes

   https://doi.org/10.1128/AEM.02138-20  

   Peters, Tracey Lee; Song, Yaxiong; Bryan, Daniel W.; Hudson, Lauren K.; Denes, Thomas G. (October 2020, Applied and Environmental Microbiology)

   Dudley, Edward G. (Ed.)

   ABSTRACT Bacteriophages (phages) are currently available for use by the food industry to control the foodborne pathogen Listeria monocytogenes . Although phage biocontrols are effective under specific conditions, their use can select for phage-resistant bacteria that repopulate phage-treated environments. Here, we performed short-term coevolution experiments to investigate the impact of single phages and a two-phage cocktail on the regrowth of phage-resistant L. monocytogenes and the adaptation of the phages to overcome this resistance. We used whole-genome sequencing to identify mutations in the target host that confer phage resistance and in the phages that alter host range. We found that infections with Listeria phages LP-048, LP-125, or a combination of both select for different populations of phage-resistant L. monocytogenes bacteria with different regrowth times. Phages isolated from the end of the coevolution experiments were found to have gained the ability to infect phage-resistant mutants of L. monocytogenes and L. monocytogenes strains previously found to be broadly resistant to phage infection. Phages isolated from coinfected cultures were identified as recombinants of LP-048 and LP-125. Interestingly, recombination events occurred twice independently in a locus encoding two proteins putatively involved in DNA binding. We show that short-term coevolution of phages and their hosts can be utilized to obtain mutant and recombinant phages with adapted host ranges. These laboratory-evolved phages may be useful for limiting the emergence of phage resistance and for targeting strains that show general resistance to wild-type (WT) phages. IMPORTANCE Listeria monocytogenes is a life-threatening bacterial foodborne pathogen that can persist in food processing facilities for years. Phages can be used to control L. monocytogenes in food production, but phage-resistant bacterial subpopulations can regrow in phage-treated environments. Coevolution experiments were conducted on a Listeria phage-host system to provide insight into the genetic variation that emerges in both the phage and bacterial host under reciprocal selective pressure. As expected, mutations were identified in both phage and host, but additionally, recombination events were shown to have repeatedly occurred between closely related phages that coinfected L. monocytogenes . This study demonstrates that in vitro evolution of phages can be utilized to expand the host range and improve the long-term efficacy of phage-based control of L. monocytogenes . This approach may also be applied to other phage-host systems for applications in biocontrol, detection, and phage therapy. 

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